Download 1.0.3. Why use Java Bluetooth stack?

Java Bluetooth stack
Design Description
Version 1.0
Doc. No.:
Java Bluetooth Stack
Design Description
Version:
1.0
Date: 2003-11-27
Revision History
Date
2003-11-22
2003-12-11
2003-12-12
2003-12-14
Version
0.1
0.2
0.5
1.0
Description
Author
Initial Draft
Minor updates
Updated RFCOMM, OBEX, Security
Marko Đurić
Tomislav Sečen
Marko Đurić
Marko Đurić
Final version
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Java Bluetooth Stack
Design Description
Version:
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Date: 2003-11-27
Table of Contents
1.
Introduction
1.1.
1.2.
1.3.
1.4.
1.5.
1.0.1. Bluetooth
1.0.2. Bluetooth software stack
1.0.3. Why use Java Bluetooth stack?
1.0.4. What is JCP? And what is JSR?
1.0.5. Why is JSR-82 important?
1.0.6. What parts of Bluetooth specifications are covered by the JSR-82?
Purpose of this document
Intended Audience
Scope
Definitions and acronyms
1.4.1. Definitions
1.4.2. Acronyms and abbreviations
References
6
6
6
7
7
7
8
8
8
8
8
8
8
9
2.
External interfaces
10
3.
Software architecture
11
3.1.
3.2.
11
11
4.
System specification
Error handling
Detailed software design
4.0.1.
4.0.2.
4.0.3.
4.0.4.
4.0.5.
4.0.6.
4.0.7.
4.0.8.
4.0.9.
5.
Approvals
Bluetooth radio
Baseband layer
Link Manager Protocol (LMP)
Host controller Interface (HCI)
Logical Link Control and Adaptation Protocol (L2CAP)
Service Discovery Protocol (SDP)
RFCOMM
OBject EXchange protocol (OBEX)
Bluetooth security
12
12
12
12
13
13
14
16
19
23
27
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Table of figures
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
Fig.
1.0.1: Bluetooth software stack ............................................................................................... 6
4.0.1: Bluetooth stack ........................................................................................................... 12
4.0.2: HCI UML class diagram ............................................................................................... 13
4.0.3: L2CAP UML class diagram ............................................................................................ 14
4.0.4: SDP UML class diagram ............................................................................................... 15
4.0.5: RFCOMM communication path ..................................................................................... 16
4.0.6: Multiple emulated serial ports ...................................................................................... 16
4.0.7: Emulating serial ports coming from two Bluetooth devices ............................................. 17
4.0.8: RFCOMM reference model ........................................................................................... 17
4.0.9: The RFCOMM communication model ............................................................................ 18
4.0.10: RFCOMM UML class diagram ...................................................................................... 19
4.0.11: OBEX hierarchy diagram ............................................................................................ 20
4.0.12: OBEX UML class diagram ........................................................................................... 22
4.0.13: Description of authentication process ......................................................................... 24
4.0.14: Description of encryption process ............................................................................... 24
4.0.15: Bluetooth security UML class diagram ......................................................................... 26
Table 3.2.1: Error handling .......................................................................................................... 11
Table 4.0.1: Entities used in authentication and encryption ........................................................... 23
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Design Description
1.
1.0.1.
Version:
1.0
Date: 2003-11-27
Introduction
Bluetooth
Bluetooth is wireless communication protocol. It was originally invented 1994. by Swedish
phone equipment maker Ericsson for wireless communication between mobile devices on short
distances (up to 100m). In 1997. some major companies (such as IBM, Intel, Nokia and Toshiba)
joined with Ericsson into Bluetooth Special Interest Group (SIG) consortium for further development
of Bluetooth protocol. After the release of the first Bluetooth specification (version 1.0), 3COM, Agere,
Microsoft and Motorola also joined the SIG consortium.
Bluetooth operates in 2.4GHz radio band that is reserved for Industrial – Scientific – Medical
(ISM) purposes. Because it communicates by radio signals, there is no need for optical visibility
between devices.
Intention of Bluetooth devices is ad-hoc connectivity of small devices like mobile phones or
PDA-s and for that reason the range is limited to 10m (max. of 100m in Class I devices – larger
devices with better power supply (more capacity)). It is mostly used for small amount of data transfer
between devices (asynchronous mode) or for speech (synchronous mode).
1.0.2.
Bluetooth software stack
Hardware used for Bluetooth communication is practically useless without some drivers. It's
like the computer hardware – if we have only hardware (i.e. peripherals like keyboards, mouse,
printers, scanners, cameras, etc.) we can't use it because the computer doesn't "know" what to do
with them. In that case we use drivers for those peripherals. In Bluetooth's "world" it is the same –
Bluetooth hardware by it self is not capable of doing anything. For that purpose we need Bluetooth
protocol stack.
Fig. 1.0.1: Bluetooth software stack
Figure 1.0.1. shows lower levels of Bluetooth software stack. At the bottom is radio layer (not
shown) – medium that transfers Bluetooth signals (radio signals at 2.4GHz). On top of radio layer is
baseband layer. It is implemented in hardware as baseband controller.
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To make Bluetooth communication possible, we must have Host Controller Interface (HCI)
firmware that implements HCI commands used for passing all data from host computer (mobile
phones, PDAs, personal computers, …) to Bluetooth device (Bluetooth chip).
Link manager (LM) (also implemented in firmware) is used to send and receive Link manager
protocol (LMP) messages that are used for link set-up, security and control.
Physical Bus is implemented as hardware (firmware) and it is used as link between Bluetooth
hardware (Bluetooth chip) and host hardware (mobile device, computer, etc.).
Upper layers are implemented as software (protocols by specifications). First of these layers
is Physical Bus and Host controller interface (drivers). They are used for access to HCI data from
hardware (and vice versa).
Higher-level drivers and protocols are device specific. If we only need audio communication,
we don't have to use any additional layers, but if we want to make data communication, then it's
important to have Logical Link Control and Adaptation Protocol (L2CAP) . It is the core layer of the
Bluetooth protocol stack and all data must pass through this layer. Purpose of this layer is to deal
with packets (Bluetooth communication is packet based communication).
L2CAP is multiplexed protocol. This mean that it can communicate with more than one upper
layer (SDP, RFCOMM, HID, TCS, …).
Finally we came to high level of Bluetooth stack. Layers here are very implementation
specific. The most used protocols here are RFCOMM and SDP. RFCOMM is replacement for "old" serial
cable connection. With this protocol implemented, we can use Bluetooth instead of serial cable, and
"don't even know that we communicate without cables". Service Discovery Protocol (SDP) is used for
discovery of other Bluetooth devices and their services.
On top of SDP is Object EXchange Protocol (OBEX). This protocol is initially defined by
Infrared Data Association (IrDA), and later adopted by Bluetooth SIG. This protocol is useful for file
transfer.
1.0.3.
Why use Java Bluetooth stack?
Bluetooth stack can be implemented on variety of platforms (J2SE, J2ME, Windows, Windows
CE, Linux, etc.). Java implementation of Bluetooth stack is good idea because Java is very distributed,
and same code can be used anywhere where exists Java run-time environment (nowadays, that is
practically any platform – from small (mobile) devices up to enterprise server systems). Java is also
very well standardized through its API specifications.
1.0.4.
What is JCP? And what is JSR?
Java Community Process (JCP) is participating project for developing and revising Java
technology specifications, reference implementations, and test suites. Over 500 companies and
individuals are now members of JCP.
Java Specification Request (JSR) is document that is submitted to Process Management Office
(PMO) that one or more JCP members send to propose the development of a new specification or
revision of existing specification.
1.0.5.
Why is JSR-82 important?
JSR-82 is a document that describes Bluetooth Java APIs. With standardized specification like
JSR-82 it is easier to develop end-user Bluetooth applications, because lot of functions are well
described in API. Target Java platform is J2ME.
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Design Description
1.0.6.
Version:
1.0
Date: 2003-11-27
What parts of Bluetooth specifications are covered by the JSR-82?
JSR-82 includes basic support for RFCOMM, OBEX and Service Discovery Protocols (SDP).
Specification is primarily targeted at native Bluetooth protocols.
Devices that use JSR-82 API must have at least 512kB of total memory (ROM/FlashROM and
RAM), Bluetooth network connection, and compliant implementation of J2ME CLDC configuration
(Java 2 Micro Edition Connected Limited Device Configuration).
1.1.
Purpose of this document
Purpose of this document is to give design description of Java Bluetooth stack.
1.2.
Intended Audience
Product supervisor, development
implementation of Bluetooth protocol stack.
1.3.
team
and
application
developers
that
use
this
Scope
Some Bluetooth protocols are already implemented in javabluetooth stack (like SDP) - they
will also be covered by this document), but this document mainly addresses to OBEX and RFCOMM
protocols and Bluetooth security.
1.4.
Definitions and acronyms
1.4.1.
Definitions
Keyword
Java
Bluetooth
Bluetooth stack
1.4.2.
Definitions
The programming language
Technology for wireless communication
Layered Bluetooth architecture
Acronyms and abbreviations
Acronym or
abbreviation
HCI
LMP
L2CAP
SDP
HID
TCS
OBEX
IrDA
J2SE
J2ME
JCP
JSR
Definitions
Host Controller Interface
Link Manager Protocol
Logical Link Control and Adaptation Protocol
Service Discovery Protocol
Human Interface Device protocol
Telephony Control Protocol specification
Object EXchange protocol
Infra-red Data Association
Java 2 Standard Edition
Java 2 Micro Edition
Java Community Process
Java Specification Request
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Design Description
PMO
CLDC
SCO
ACL
BCC
DLC
1.5.
Version:
1.0
Date: 2003-11-27
Process Management Office
Connected Limited Device Configuration
Synchronous Connection-Oriented protocol
Asynchronous ConnectionLess protocol
Bluetooth Control Center
Data Link Connection
References
B. Hopkins, R. Anthony, Bluetooth for Java, Apress, 2003.
Specification of the Bluetooth System, specification Vol.1, version 1.1, Bluetooth SIG, 2001.
Java APIs for Bluetooth Wireless Technology (JSR-82), specification version 1.0a, 2002.
http://wireless.java.sun.com/midp/articles/Bluetooth1
http://www.jcp.org/en/home/index
http://www.niksula.cs.hut.fi/~jiitv/bluesec.html
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Design Description
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External interfaces
There are no external interfaces to other projects / groups, but since work is based on the
javabluetooth stack (javabluetooth.sourceforge.net) one could consider the existing source code to be
an (external) interface.
Since L2CAP protocol layer is the one on top of which RFCOMM will be built, one can consider
L2CAP to be an external interface for RFCOMM, and HCI classes and methods as an interface to
implementing security.
The class diagrams for the L2CAP and HCI layers as they were originally built in the
javabluetooth project can be found later in this document.
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Design Description
3.
3.1.
Version:
1.0
Date: 2003-11-27
Software architecture
System specification
Final project output needs to behave exactly as specified by the JSR-82 specification, so
system specification=JSR-82.
3.2.
Error handling
Since the final result of this project will in fact be a library, it will only respond to the
exceptions originating from any layer in the stack and pass them (maybe as an different exception) to
the user application which will be using the stack. Some internal software exceptions will be handled
internally, and the operations involved retried, but these exceptions are protocol specific and they
won't be discussed any further throughout this document.
User application will have to deal with following error conditions:
Error
Device goes out of range during
communication
Error while initializing hardware (i.e.
setting COM speed)
Error with security settings
Action
Implement timeouts and retransmission
Fatal error, instruct user to check hardware
settings
Instruct user to check devices security
options
Table 3.2.1: Error handling
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Design Description
4.
Version:
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Detailed software design
Bluetooth stack has layered structure, like referent ISO/OSI network model. It is composed of
protocols that are specific to Bluetooth (L2CAP, SDP, etc.) and other adopted protocols (i.e. OBEX).
There are four main groups in Bluetooth stack:
- Bluetooth core protocols – Baseband, Link Manager Protocol, L2CAP and SDP
- Cable replacement protocol – RFCOMM
- Telephony control protocol – TCS Binary
- Adopted protocols – PPP, UDP/TCP/IP, OBEX, WAP
Fig. 4.0.1: Bluetooth stack
4.0.1.
Bluetooth radio
Bluetooth radio is hardware for wireless Bluetooth communication. It is the lowest layer of
Bluetooth stack and it is in charge of communication between two or more Bluetooth devices.
Bluetooth radio signals are in frequency range of 2.4GHz up to 2.4835GHz divided in 79 channels with
1MHz spacing between channels. For added security, channels use frequency hoping (frequency is
changed in pseudo-random pattern 1600 times per second).
4.0.2.
Baseband layer
Baseband layer enables physical radio-frequency (RF) link between Bluetooth enabled devices
that make connection. Its function is to manage Bluetooth channels (frequency hoping, time-slots,
etc.) and packet transmissions.
4.0.3.
Link Manager Protocol (LMP)
LMP is responsible for link set-up, managing security (authentication, encryption) between
Bluetooth devices and control of Bluetooth devices. Link manager messages have higher priority than
user data (because the control is more important than user data – if there is no control, there is no
data either).
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Transport layer provides the ability to transfer data without intimate knowledge of data.
There are several types of transport layers – USB, RS232, UART, HCI, RFCOMM, TCP/IP, etc.
4.0.4.
Host controller Interface (HCI)
HCI provides a uniform interface method of accessing the Bluetooth hardware capabilities.
HCI commands are implemented in HCI firmware by accessing baseband commands, link manager
commands, hardware status registers, control registers, and event registers. In come cases there is
also Host Controller Transport Layer as an intermediate layer for communication between HCI
firmware and host HCI driver.
HCI UML class diagram:
Fig. 4.0.2: HCI UML class diagram
4.0.5.
Logical Link Control and Adaptation Protocol (L2CAP)
L2CAP adapts upper-layer protocols to the baseband layer by providing Synchronous
Connection-Oriented (SCO) and Asynchronous ConectionLess (ACL) data services to upper-layer
protocols. It has protocol multiplexing capability (this means that it's possible to use more than one
higher-layer protocol), segmentation and reassembly operation of data packets, and group
abstractions.
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L2CAP class diagram:
Fig. 4.0.3: L2CAP UML class diagram
4.0.6.
Service Discovery Protocol (SDP)
SDP is used for applications to discover which services are available and to determine the
characteristics of those available services on Bluetooth devices.
The service discovery mechanism provides the means for client applications to discover the
existence of services provided by server applications as well as the attributes of those services. The
attributes of a service include the type or class of service offered and the mechanism or protocol
information needed to utilize the service.
The server maintains a list of service records that describe the characteristics of services
associated with the server. Each service record contains information about a single service. A client
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may retrieve information from a service record maintained by the SDP server by issuing an SDP
request.
There is maximum of one SDP server per Bluetooth device.
SDP class diagram:
Fig. 4.0.4: SDP UML class diagram
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4.0.7.
Version:
1.0
Date: 2003-11-27
RFCOMM
The RFCOMM protocol provides emulation of serial ports over the L2CAP protocol. It supports
up to 60 simultaneous connections between Bluetooth devices, but the real number of simultaneous
connections is implementation specific.
Complete communication path in RFCOMM involves two separate applications that are run on
two different devices with communication segment between them.
Application
Device A
Communication
segment
Application
Device B
Fig. 4.0.5: RFCOMM communication path
RFCOMM has emulated RS-232 Circuits as follows:
Pin:
Circuit Name:
102
Signal Common
103
Transmit Data (TD)
104
Receive Data (RD)
105
Request To Send (RTS)
106
Clear To Send (CTS)
107
Data Set Ready (DSR)
108
Data Terminal Ready (DTR)
109
Carrier Detect (CD)
125
Ring Indicator (RI)
It is possible to have multiple serial ports between two devices – a Data Link Connection
Identifier (DLCI) identifies an ongoing connection between a client and a server application. 6 bits
represent the DLCI, but values 1 (reserved due to concept of Server Channels), 62 and 63 are
unusable.
Fig. 4.0.6: Multiple emulated serial ports
Multiple emulated serial ports and multiple Bluetooth devices – if a Bluetooth device supports
multiple emulated serial ports and the connections are allowed to have endpoints in different
Bluetooth devices, then the RFCOMM entity must be able to run multiple multiplexer sessions.
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Fig. 4.0.7: Emulating serial ports coming from two Bluetooth devices
Service definition model:
Fig. 4.0.8: RFCOMM reference model
The lowest layer here is also Baseband and Baseband protocol is defined by Bluetooth
specification.
L2CAP layer is capable of channel multiplexing.
Server applications are registered on local device, and SDP provides services for client
applications to discover how to reach server applications on other devices.
RFCOMM provides a transparent data stream and control channel over an L2CAP channel,
and also multiplexes multiple emulated serial ports.
The Port emulation entity maps a system-specific communication interface (API) to the
RFCOMM services. In combination with RFCOMM it makes the port driver.
Applications are used for utilization of serial port communication interface.
Frame types supported in RFCOMM:
Name:
Set Asynchronous Balanced Mode (SABM)
Unnumbered Acknowledgement (UA)
Disconnected Mode (DM)
Disconnected (DISC)
Unnumbered Information with Header check (UIH)
Type:
command
response
response
command
command and response
Specification TS 07.10 defines a multiplexer that has dedicated control channel, DLCI 0. It is
used to convey information between two multiplexers.
Supported Control Channel Commands:
Test Command (Test)
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Flow Control On Command (FCon)
Flow Control Off Command (FCoff)
Modem Status Command (MSC)
Remote Port Negotiation Command (RPNC)
Remote Line Status (RLS)
DLC parameter negotiation (PN)
Non Supported Command response (NSC)
Start-up procedure of serial port communication over RFCOMM:
- Establish an L2CAP channel to the peer RFCOMM entity, using L2CAP service primitives
- Start the RFCOMM multiplexer by sending SABM (Set Asynchronous Balanced Mode)
command on DLCI 0 and await UA response from peer entity.
- Data Link Connections (DLC) can be now established for user data traffic.
Closedown procedure of serial port communication over RFCOMM:
The Device closing the last connection (DLC) on a particular session is responsible for closing
the multiplexer by closing the corresponding L2CAP channel. Closing the multiplexer by first sending a
DISC command frame on DLCI 0 is optional, but it is mandatory to respond correctly to DISC (with
UA response).
Link-loss handling:
If an L2CAP link loss notification is received, the local RFCOMM entity is responsible for
sending a connection loss notification to the port emulation/proxy entity for each active DLC.
Flow control in the wired systems is based on RTS/CTS signals, but the flow control between
RFCOMM and the lower layer L2CAP depends on the service interface supported by the
implementation. RFCOMM has also it's own flow control mechanisms, and L2CAP relies on the flow
control mechanism provided by Link Manager layer in the Baseband.
Interaction with other entities:
Fig. 4.0.9: The RFCOMM communication model
Type 1 devices are communication endpoints such as computers and printers.
Type 2 devices are part of a communication segment (i.e. modems).
The Port Emulation Entity maps a system specific communication interface (API) to the
RFCOMM services.
The Port Proxy Entity relays data from RFCOMM to the external RS-232 interface linked to a
DCE (Data Circuit-Terminating Equipment) – communication parameters are set according to received
RPN commands.
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RFCOMM Class-diagram:
Fig. 4.0.10: RFCOMM UML class diagram
Server creation and initialization through RFCOMMServer class.
RFCOMMConnection class calls RFCOMMConnection that creates new L2CAP channel on
which RFCOMM based communication will be established.
RFCOMMConnectionCreator class is used for establishing L2CAP communication channel.
DLC class is holding the channel ID, direction and all other parameters associated with each
of DLC connections. It also creates and sends, receives and parses L2CAP packets.
CODES class contains codes for RFCOMMConnection class.
4.0.8.
OBject EXchange protocol (OBEX)
OBEX is protocol that Bluetooth adopted from IrDA. Original name of this protocol (defined by
IrDA) is IrOBEX, but shorter name OBEX is used instead. By adopting OBEX, it is possible to use it
over IrDA IR (light) or Bluetooth technology (radio signals).
OBEX was developed to exchange data objects over an infrared link and was placed within
the IrDA protocol hierarchy. However, it can appear above other transport layers, now RFCOMM and
TCP/IP. At this moment, it is worth mentioning that the OBEX over TCP/IP implementation is an
optional feature for Bluetooth applications supporting the OBEX protocol.
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The IrOBEX protocol follows a client/server request-response paradigm for the conversation
format.
Applications
Synchronisation
File transfer
Object
vCard, vCal, ...
Generic format
vCard, ...
Session layer
Transport layer
Adaption layer
OBEX
RFCOMM
TCP
IP
SDP
Service
Discovery DB
L2CAP
Fig. 4.0.11: OBEX hierarchy diagram
In the Bluetooth system, the purpose of the OBEX protocol is to enable the exchange of data
objects. The typical example could be an object push of business cards to someone else. A more
complex example is synchronizing calendars on multiple devices using OBEX.
For the Object Push and Synchronization applications, content formats can be the vCard,
vCalendar, vMessage, and vNotes. Those content formats describe the formats for the electronic
business card, the electronic calendar and scheduling, the electronic messages and mails, and the
electronic notes, respectively.
OBEX protocol can transfer an object by using the Put and Get operations. One object can
be exchanged in one or more Put requests or Get responses. The model handles both information
about the object (e.g. type) and object itself. It is composed of headers, which consist of a header ID
and value. The header ID describes what the header contains and how it is formatted, and the
header value consists of one or more bytes in the format and meaning specified by header ID.
The specified headers are: Count, Name, Type, Length, Time, Description, Target, HTTP,
Body, End of Body, Who, Connection ID, Application Parameters, Authenticate Challenge,
Authenticate Response, Object Class, and User-Defined Headers.
Session protocol – the OBEX operations are formed by response-request pairs. Requests are
issued by the client and responses by the server. After sending a request, the client waits for a
response from server before issuing a new request.
Connect operation:
An OBEX client starts the establishment of an OBEX connection.
At the remote host, the OBEX server receives the Connect-request, if it exists. The server
accepts the connection by sending the successful response to the client.
Disconnect operation:
The disconnection of OBEX session occurs when an application, which is needed for an OBEX
connection, is closed or the application wants to change the host to which the requests are issued.
The client issues the Disconnect-request.
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Put operation:
When the connection has been established between the client and server the client is able to
push OBEX objects to the server.
A Put-request consists of one or more request packets, depending on how large the
transferred object is, and how large the packet size is. A response packet from the server is required
for every Put-request packet.
Get operation:
When the connection has been established between the client and server, the client is also
able to pull OBEX objects from server.
Other operations:
Other operations consist of SetPath, and Abort operation.
OBEX over RFCOMM – The Bluetooth devices supporting the OBEX protocol must satisfy the following
requirements:
The device supporting OBEX must be able to function as a client, a server, or both.
All servers running simultaneously on a device must use separate RFCOMM server channels.
Applications (service/server) using OBEX must be able to register the proper information into
the service discovery database. This information for different application profiles is specified in the
profile specifications.
OBEX server start-up on RFCOMM:
When a client sends a connecting request, a server is assumed to be ready to receive
requests. However, before the server is ready to receive (i.e. is running) certain prerequisites must be
fulfilled before the server can enter the listening mode:
The server must open an RFCOMM server channel
The server must register its capabilities into the service discovery database
Connection establishment:
A client initiates the establishment of a connection. However, the following
sequence of tasks must occur before the client is able to send the first request
for data:
By using the SD protocol described in SDP specification, the client must discover the proper
information (e.g. RFCOMM channel) associated with the server on which the connection can be
established.
The client uses the discovered RFCOMM channel to establish the RFCOMM connection
The client sends the Connect-request to the server, to establish an OBEX session. The session
is established correctly if the client receives a successful response from the server.
Disconnection:
Using the Disconnect-request does the disconnection. When the client has received the
response, the next operation is to close the RFCOMM channel assigned to the OBEX client.
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Fig. 4.0.12: OBEX UML class diagram
OBEXClient class creates RFCOMM DLC on the client side that is used to connect to the server
with the data received using SDP. It also implements push, pull and abort operations.
ClientSession interface provides methods for OBEX requests and provides way to define
headers for OBEX operations (CONNECT, PUT, GET, SETPATH and DISCONNECT).
HeaderSet interface defines the methods that set and get values of OBEX headers.
PasswordAuthentication class holds user name and password combinations.
Authenticator interface provides a way to respond to authentication challenge and
authentication response headers. When a client or a server receives authentication challenge or
authentication response header the onAuthenticationChallenge() and onAuthenticationResponse()
methods are called respectively, by the implementation.
Operation interface provides ways to manipulate a single OBEX PUT or GET operation.
SessionNotifier interface defines a connection notifier for server-side OBEX connections.
When a SessionNotifier is created and calls acceptAndOpen() method, it will begin listening for clients
to create a connection at the transport layer.
ServerRequestHandler class defines an event listener that will respond to OBEX requests
made to the server by appropriate response codes.
OBEXServer class creates RFCOMM DLC on the server side that listens for OBEX client
requests. When the request is received, connection is established.
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4.0.9.
Version:
1.0
Date: 2003-11-27
Bluetooth security
JSR-82 API needs implementation of Bluetooth Control Center (BCC) that specifies basic
properties of Bluetooth device. One of those properties is Bluetooth security.
BCC sets security level for device, maintains a list of earlier discovered devices (trusted one
and not trusted one), it gives mechanism for pairing up and authorization of devices that are
communicating for the first time.
There is need for supply BCC with primary security mechanisms and interfaces. Majority of
this part is closely related with Link and Baseband layer, so the interfaces to those layers will be
implemented by HCI layers method invocations concerning authentication, authorization and
encryption processes.
During the process of authentication need for PIN (Personal Identification Number) is
supposed. PIN can exist in device's memory or user can supply one. Except the fact about who is
supplying PIN decision must be made about how many various PINs you can enter (one or more).
The most important thing about PIN is that it should never be transferred between devices. It is only
used for personal authentication.
Basic Bluetooth security modes already implemented by the Bluetooth specification:
Mode 1: No security measures. Every other device can contact this device without going
through authentication, encryption and authorization processes.
Mode 2: Security procedures are initiated after channel establishment request has been
received at L2CAP level
Mode 3: Security measures are activated at LMP level before a channel is created and opened
for communication
There are four entities for maintain security at the link
BD_ADDR
Private user key, authentication
Private user key, encryption
Configurable length (byte-wise)
RAND
layer:
48 bits
128 bits
8-128 bits
128 bits
Table 4.0.1: Entities used in authentication and encryption
Process of authentication is based on shared link key between devices. If two devices
communicates for the first time, there is no link key and it needs to be created. In order to create link
key, initialization key must be created first, but that is always case because it is automatically created
at the beginning of the communication.
Initialization key is derived from BD_ADDR, IN_RAND (random number), PIN length and PIN
code using algorithm E22. After initialization key has been created, devices forms the link key. Link
key can be a unit key or combinational key. Unit key is generated with first usage of the device and it
is stored in non-volatile memory. It could be changed, but not very easy. Algorithms for link key
generation are described in Bluetooth specification v1.1.
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Java Bluetooth Stack
Design Description
Version:
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Date: 2003-11-27
Authentication begins after link key is generated.
Verifier (Device A)
Claimant (Device B)
RAND(A)
BD_ADDR(B)
RAND(A)
E1
RAND A
Link key
E1
BD_ADDR(B)
Link key
SRES
ACO
ACO
SRES'
?=
SRES
SRES'
?=
SRES
Fig. 4.0.13: Description of authentication process
At the beginning of authentication process the verifier sends the random number to claimant.
Both participants then use authentication function E1 with the claimant's Bluetooth Device Address,
shared link key and sent random number. Claimant then sends response to verifier, and verifier
compares response with his result. If they match, the claimant is authenticated. To achieve mutual
authentication, the claimant just need to issue another random number to verifier and wait for
response.
If the authentication fails, there is a delay between new authentications, and that delay
doubles each time that authentication fails, until the maximum delay time is reached (from the same
address).
Another important parameter in encryption process is Authenticated Ciphering Offset (ACO).
Along with link key and generated random number it makes input entries for E3 algorithm for
generation of encryption key. ACO and link key are known to both devices, and every time when
device enters encryption mode new encryption key is generated.
Device A (master)
BD_ADDR(B)
clock(A)
Device B
RAND A
E0
Kc
BD_ADDR(B)
clock(A)
Kc
Kstr
Data A -> B
Data B -> A
E0
Kstr
Data
Data A -> B
Data B -> A
Fig. 4.0.14: Description of encryption process
Encryption algorithm E0 has following parameters – BD_ADDR, 26 bits of master real-time
clock and encryption key Kc. EN_RAND is issued by master before entering encryption mode. With E0
encryption key is derived by another encryption key.
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Java Bluetooth Stack
Design Description
Version:
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Date: 2003-11-27
JSR-82 API implemented security features:
Security measures by JSR-82 API specification are implemented in link layer. JSR-82 specifies
API functions to activate authentication, encryption and authorization functions. One way for using
those function is to specify them as optional parameters in URL of service that is wanted to use.
Bluetooth Server can request authentication by adding the authenticate parameter to the
connection URL string
(String url = "btspp://localhost:81283209832382323…..32;authenticate=true").
Same rule applies for authorization and encryption keywords.
Clients can request authentication and encryption in the same way – there is no point of
using authorization for clients so it's not allowed for clients at all.
When server calls Connector.open() method, a new Service Record is created based on
optional attributes that reside in the URL string. That record can be edited afterwards if there is any
need to do it. Record after that goes to SDDB, before a client makes a connection.
At the client side client application opens a connection to that service. I order to achieve its
goal it needs to go through all security requirements specified in server application's record. Those
security procedures are activated through HCI interface method invocation. BCC is example of
centralized security manager that manages all this connection requests and takes specified actions in
order to protect security policy.
Another issue concerns applying security policies on already created connections. Suppose
that devices have already established connection and remote device wants to authenticate itself. BCC
has interface to link layer (through interface to HCIDriver).
Bluetooth devices can be divided in trusted and non-trusted. That's another thing to worry
about. BCC has a table of known devices. Devices that are marked as trusted have access to all
services no matter of service security attributes (encryption, authentication, authorization). Naturally,
there are non-trusted ones that have limited access.
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Java Bluetooth Stack
Design Description
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Date: 2003-11-27
Bluetooth security class diagram:
Fig. 4.0.15: Bluetooth security UML class diagram
BCC class is used for sending authentication, authorization, encryption, security and PIN
requests. It is also responsible for setting security at link level, and for finding devices.
SDPServer class resolves and creates L2CAP channel, register and unregister services and
gets attributes and service record handles.
L2CAPLink class is responsible for L2CAP channel connection and disconnection (closing
channel). It sends and receives L2CAP packets, and makes L2CAP requests.
RemoteDevice class represents the security features of remote devices, like Bluetooth
address, friendly name, requested security level, etc. There is also possibility for finding out security
measurements set on the device.
HCIDriver class is responsible for communication with host controller interface (HCI) layer. It
sends HCI packets, and is used for register and unregister L2CAP link.
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Java Bluetooth Stack
Design Description
5.
Version:
1.0
Date: 2003-11-27
Approvals
Name
Title
Date
yyyy-mm-dd
Signature
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